System and method for providing communications services

ABSTRACT

A routing system for providing a communications service via a telecommunications network includes a switch communicatively coupled to a first interface, a second interface, and a third interface. Each interface is operable to relay an audio signal between a station and the switch. A signal processor is communicatively coupled to the switch and operable to monitor the audio signal for a trigger signal as the audio signal is relayed between the first interface and the second interface. The signal processor is further operable to selectively activate the switch upon detection of the trigger signal to communicably couple the third interface to the first interface and/or the second interface.

This is a continuation-in-part application of application Ser. No. 10/430,791 filed May 6, 2003.

FIELD OF THE INVENTION

This application relates to communication service systems and methods of providing communications services.

BACKGROUND OF THE INVENTION

Callers using communications devices have several services available to them from various telecommunications service providers. Some service providers offer automated services to callers without involving an operator. For example, a caller may attempt to use a telephone to place a call to an individual. If the call is long distance, and the telephone (or network) that the caller is using does not support direct dialing of a long distance number, the method of payment must be arranged to complete the call. An example of such services is automatic billing selection in which a program is run offering a caller payment options for the call, such as by using a calling card. The caller then enters the proper digits corresponding to payment by calling card, enters his card information, and the call is connected without involving an operator.

In a further example, if the call is not completed, an automatic call-back feature may be offered in which the dialed number is dialed again automatically. Such auto-redial is chosen or accepted by the caller, and the system from time to time redials the number for a fee until a connection is made. Such offerings are made automatically, again, without involving an operator.

Other services that are available from service providers to callers involve human operators. Examples of known operator assisted services provided to callers include directory assistance, collect calling assistance, and dialing assistance. In directory assistance calls, a user dials a predetermined number that accesses an operator. The caller provides the operator the city or other geographic region and the name of the person or business s/he is attempting to reach. The operator then accesses a database in an effort to find the desired number. If the operator finds the number, the caller is informed of the number and/or connected by the operator.

A variety of architectures and networks are known to provide contexts within which such services can be provided. Both automated and operator assisted services are available through various communications networks from various service providers connected to such networks. Examples of common communications networks are disclosed in U.S. Pat. No. 5,289,535 to Bogart, et al. and U.S. Pat. No. 6,411,624 to Christie et al., the disclosures of which are hereby expressly incorporated by reference herein.

SUMMARY

A routing system for providing a communications service via a telecommunications network includes a switch communicatively coupled to a first interface, a second interface, and a third interface. Each interface is operable to relay an audio signal between a station and the switch. A signal processor is communicatively coupled to the switch and operable to monitor the audio signal for a trigger signal as the audio signal is relayed between the first interface and the second interface. The signal processor is further operable to selectively activate the switch upon detection of the trigger signal to communicably couple the third interface to the first interface and/or the second interface. The signal processor may comprise a digital signal processor, a DTMF detector, or a speech recognition unit. The trigger signal may be a DTMF tone or a spoken word, and may be transmitted by either the calling station or the called station

Additionally, a method for providing a translation service via a network includes receiving a call at a local exchange from a calling communication device associated with a first number and indexing the first number into a database and selectively routing the call to a switch as a function of the first number. The method also includes receiving the call and a second number associated with a called communication device at the switch, and routing the call through the switch to the called communication device as a function of the second number. Additionally, the method includes monitoring the call between the calling communication device and the called communication device for an audio signal with a processor, and upon detection of the audio signal routing the call through the switch to an operator communication device.

Additional features and advantages of the invention will become apparent to those skilled in the art upon consideration of the following detailed description of a preferred embodiment exemplifying the best mode of carrying out the invention as presently perceived.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram of one embodiment of an enhanced services platform showing an exemplary caller equipment, a routing system, and an operator equipment;

FIG. 2 is a diagram of one embodiment of the operator equipment in the context of a translation service provided to a caller;

FIG. 3 is a diagram of one embodiment of the routing system and the operator equipment in the context of an e-mail service provided to a caller;

FIG. 4A is a flow chart showing one embodiment of a software menu module and the operation and steps involved when the menu module is run or accessed;

FIG. 4B is a flow chart showing one embodiment of a software main module including initial call routing determinations, showing the operation and steps involved when a call is received at the routing system;

FIG. 4C is a flow chart showing one embodiment of a line condition module showing the operation and steps involved with monitoring the condition of the line;

FIG. 4D is a flow chart showing one embodiment of a billing or payment module, showing the operation and steps involved when the billing system module is accessed or executed;

FIG. 4E is a flow chart showing one embodiment of an operator system module showing steps and operation when a call is received at the operator equipment;

FIG. 5 is a diagram of one embodiment of an illustrative enhanced services platform showing an exemplary switch configuration, an exemplary computer configuration, and exemplary connections, and of a communication network, the Internet, and memory in the form of databases accessible by the computer;

FIG. 6 is a diagram of one embodiment of a portion of a computer showing an illustrative “auto op” computer, and illustrative programs and interaction between and among the auto op computer, programs, switch, databases, and other portions of the computer;

FIG. 7 is a flow chart showing one embodiment of a call tour lookup used once a call reaches the auto op computer to determine how a call is to be handled;

FIG. 8 is a diagram of another embodiment of an enhanced services platform;

FIG. 9 is a system level block schematic diagram of an embodiment of an enhanced services platform;

FIG. 10 is a more detailed system level block schematic diagram of an embodiment of the enhanced services platform of FIG. 9;

FIG. 11A is a portion of a flow chart showing an illustrative method of operation for the enhanced services platform of FIG. 9; and

FIG. 11B is a portion of a flow chart showing an illustrative method of operation for the enhanced services platform of FIG. 9.

DETAILED DESCRIPTION

Referring to FIGS. 1-3, enhanced services platform 10 includes operator services architecture 12 having operator equipment 14 and a routing system 16 to selectively permit communication between an operator and a caller. The caller accesses an operator having access to operator equipment 14 through link 17. Using caller equipment 18, the caller can access this operator in any number of ways, as described more fully below. The operator and caller communicate to complete the services requested by the caller.

As shown in FIGS. 2 and 3, enhanced services platform 10 further includes software 20 cooperating with other portions of routing system 16 and operator services architecture 12. As a result of this cooperation, a caller gains access to the enhanced services provided as part of enhanced services platform 10. As shown in the embodiment of FIG. 5, routing system 16 includes a switch 22. In another embodiment, routing system 16 is operably coupled to a switch that is included in existing system architecture, such as network 40 of FIG. 5. Thus, enhanced services platform 10 can take the form of a platform that includes its own switch(es) or a platform that is implemented into existing switching architecture where the switch(es) is (are) already in place.

Enhanced services platform 10 is capable of automatically connecting a caller to enhanced services as described herein. Enhanced services platform 10 selectively enables a caller to access, and/or fund, the enhanced service desired by the caller. As suggested by FIGS. 2 and 3, enhanced services are provided by a live operator, who provides one or more of e-mail services 148 including preparation and sending, and translation or interpretation services 150 (hereinafter “translation services”).

As shown by way of illustration in FIG. 5, operator equipment 14 may include, for example, operator communication device 26 including a listening device 28 and speaking device 30. Listening device 28 and speaking device 30 may be part of a single apparatus such as a headset 46 commonly used by operators, shown in FIG. 5 separated from other operator equipment 14. As shown in FIG. 5, operator communication device 26 may include a separate operator base or “teleset” 42 that receives a call from routing system 16. As shown in FIG. 5, teleset 42 may include a standard cradle and receiver, may be coupled to headset 46, or may include other suitable listening and speaking devices 28, 30.

Further, operator equipment 14 may include an operator information device, such as an operator computer or work station 44 as shown in FIG. 5, for example. Using operator equipment 14, an operator may engage the caller in conversation and render services requested by the caller. For example, the information device may be an e-mail device 32, as shown in FIG. 3, used by the operator to enter information to compose and send an e-mail according to the instruction of the caller. Alternatively, the information device may be used by the operator as suggested in FIG. 2 to assist the operator in providing translation services for the caller during a call. In this example, the operator may have access through the information device to a database or the Internet to look up words with which the operator is not familiar. The information device and communication device 26, although shown separate, may be part of a single device such as a computer that can serve as one, the other, or both of a communications device and an information device.

Caller equipment 18 may include, for example, a corded or cordless telephone, a cellular or satellite telephone, a personal digital assistant, a computer, or other communications devices. Caller equipment 18 enables a caller to initiate a communications session, such as a telephone call (referred to herein as a “call”), in which the caller may access enhanced services. As shown in FIG. 5, caller equipment 18 is operatively coupled, as described more fully below, to a switch 22 by link 24. Switch 22 may be coupled to other switches 34 and links 36 which in turn are coupled to other caller equipment 38, and/or further links and switches, etc., forming a communications network 40, such as shown in FIG. 5.

Routing system 16, shown illustratively in FIG. 5 as including switch 22, is accessible by a caller in a variety of ways. For example the caller may dial a toll free number, dial a local number, or enter a sequence of digits and/or symbols in a call. Additionally, routing system 16 and customer equipment 18 can be connected directly from the local exchange when the originating number is defined as one to be routed to switch 22. Further, other providers of telecommunications services may have software and architecture that cooperate to offer a caller using such services an opportunity to access the enhanced services described herein. Such other providers' software and architecture may be programmed to dial an access number which connects the caller to routing system 16. Any of these numbers or digit and/or symbol sequences can constitute an “access number” which routes a call to routing system 16, switch 22, operator equipment 14, a call tour, or a menu module 78, within the meaning of the term “access number” as used herein. Further still, caller equipment 18 may be configured to connect directly to routing system 16—for example to first switch 66 described below—to permit the caller equipment to access the enhanced services platform 10 without entering a particular access number.

As illustrated in FIG. 5, enhanced services platform 10 further includes a computer 50 operatively coupled to switch 22. As is known to those of ordinary skill in the art, computer 50 processes calls initiated by the caller, and cooperates with switch 22 to route the call according to certain information provided by the caller and/or identifiable about the call. Computer 50 can include one or more separate computers, which can take a variety of forms. Although the term “computer” is used herein, the term is not intended to be limiting, and it should be understood that other means of processing information are within the scope of this disclosure and can be used in place of the embodiment(s) of computer 50 illustratively described herein. For example, other suitable computing systems may include one or more processors, one or more servers performing one or more functions each, and other suitable arrangements. Switch 22 can also take a variety of forms, including but not limited to a Harris 20-20 and an Alcatel Megahub switching system, described in more detail below.

As shown in FIG. 5, computer 50 is operatively coupled to memory 52. Memory 52 illustratively includes first database 54 and second database 56, each accessible by computer 50. First database 54 includes originating number data to determine whether specific services are supported by the number from which the caller is calling. Second database 56 includes data relating to the routing and/or handling of calls. Other databases, for example database 58 may also be coupled to computer 50. As shown in FIG. 5, database 58 is accessed by computer 50 through a communications network. In this exemplary configuration, database 58 is part of and accessible through a service offered through SBC SNET (formerly Southern New England Telephone of New Haven, Conn.) (“SNET”), permitting account monitoring and validity determination of a payment method selected by the caller. Database 58 contains information from LIDB services which indicate the validity of credit cards, calling cards, and other methods of payment.

As explained further below, a link can be established with one or more local databases 54, 56 or database 58 to determine the validity of a particular payment method, so that the call can be terminated, for example, once the account has insufficient credit to cover a particular charge. The above description of databases 54, 56, 58 are exemplary, and as known by those of ordinary skill in the art, data contained in databases can be stored in numerous locations, a single location, can be accessed in a variety of ways, and can be stored in a number of tabular or other formats. The operation of computer 50 and memory 52 is described in more detail below.

Illustratively, computer 50 comprises a plurality of microprocessing units each performing one or more functions. As illustrated in FIG. 5, one possible configuration of computer 50 includes an automated operator (“auto op”) computer 60 and a validation engine or server 62. Auto op computer 60 illustratively is a computer including an Intel® Pentium III® motherboard (not shown), two serial communications ports (not shown) a Dialogic 240SC T1 card (“communications card”) (not shown) for coupling to switch 22, a monitor, keyboard and a mouse (the latter three components not shown). As illustrated in FIG. 5, auto op computer 60 and validation engine 62 are coupled with link 64. Switch 22 illustratively comprises a first switch 66, shown as a MegaHub® available from Alcatel with United States offices in Calabasas, Calif., a local switch 68, and an automatic call distribution (ACD) switch 48. Illustratively, local and ACD switches are 20-20 switching systems available from Teltronics, Inc. of Sarasota, Fla., sometimes referred to as Harris 20-20 switches.

Referring illustratively to FIG. 5, when a call is placed by the caller, the call is received at a first switch 66 which makes an initial routing decision by querying first routing tables (not shown). If first switch 66 concludes the call should be routed so as to receive enhanced services, then the call is presented or connected to local switch 68. Determinations made by first switch 66 may be based on such information about the call such as an originating number, the circuit on which the call comes to first switch, a number that was dialed by the caller, and the like.

First switch 66 sends a message to local switch 68 concerning the call. Computer 50 and local switch 68 cooperate to evaluate the message to determine further routing of the call. The message, illustratively called a “Present New Call HIL” message, is sent to auto op computer 60 through link 70. The Present New Call HIL message provides call information to auto op computer 60. This call information may include the circuit the call is on, the access number used to reach local switch 68, the originating telephone number, and the like. This call information is illustrative, and it is within the scope of this disclosure to include additional information, other information, or to not include one or more of the listed information.

As a result of the routing determination made by local switch 68, local switch 68 provides information about the call to auto op computer 60. Auto op computer 60 connects to the call circuit once it is ready, and the call is now under the control of the auto op computer 60. Auto op computer 60 now can interact with the caller, and/or the call, to set up which service will be provided and/or how payment is to be made.

In one exemplary configuration, auto op computer 60 creates a validation packet to send to the validation engine 62 to determine if the originating number is valid to originate the call and access the enhanced services platform 10. Auto op computer 60 sends the packet to validation engine 62, which determines validity through cooperation with Oracle application and database servers 74, 75. If the number is valid, auto op computer 60 maintains the call. If the number is not identified as valid, auto op computer 60 sends a release request message to the switch to disconnect the call—the call is dropped by the switch and the voice circuit is placed in an idle state. Instead of dropping the call, it is within the scope of this disclosure to present the caller with other options, for example, other payment options or other service options, or to connect the call with a live operator.

Referring to FIGS. 6 and 7, auto op computer 60, if the call is continued, determines what kind of call tour to provide for the call. Auto op computer 60 thus creates an information packet, illustratively a TCP/IP packet. The packet may contain the access number (such as an 800 toll free access number), the originating telephone number, and a database service number.

In an effort to determine what call tour to provide, and/or other call treatment details such as payment method, auto op computer 60 communicates with Oracle database server 75 through the Oracle application server 74 to so determine the call tour. The packet is sent over an Ethernet LAN 72 (sometimes referred to herein as “Ethernet” or “LAN”) to Oracle Application Server 74 which controls and manages access to different services provided by the Oracle database.

The packet is processed by the database server, as shown in FIG. 7. By way of illustration, database server 75 accesses two tables. The first accessed is the ANI (Automatic Number Identification) table which contains numbers for which access is provided. The second is the auto op 800 table. Each of the tables contains information which is used to determine what service to provide for the call.

When a call comes in from caller equipment 18, the originating number of which is not loaded in the ANI database, the access number is looked up in the Auto Op 800 table (or database) to determine what kind of service to provide for the call—to determine a default class of service for calls that are not identified by the originating ANI database. A flowchart showing an exemplary lookup sequence and related steps is depicted in FIG. 7.

The database service creates a return packet of information which is returned to auto op computer 60 via TCP/IP. Auto op computer 60 parses the information from the packet which includes the call tour to be played, opening brand, exit brand, etc. Thus, auto op computer 60 has sufficient information about how to treat the call.

The above actions and interactions, and others described herein, are carried out at least in part by providing instructions to processor(s) in computer 50 in the form of software which may be stored in a number of locations or in a single location. Illustratively, software 20 is stored in memory 52; however, software 20 can be stored in any suitable medium accessible by a computer such as computer 50 to run the instructions or modules of software 20.

A particular configuration of software 20 is illustrated in FIGS. 4A-E. Software 20 includes instructions 76 that cause computer 50 to cooperate with switch 22 to connect the caller, specifically caller equipment 18, to operator equipment 14 accessible by a live operator serving in the enhanced services platform 10. Instructions 76 of software 20 can be stored at one or more locations and can be accessible by one or more computers, servers, operator work stations, and the like. Portions of instructions 76 are described as “modules” to facilitate discussion of the function of various portions of the instructions 76; however, use of the term modules is not intended to be limiting, but rather to indicate a portion of instructions 76 that carries out a function and that may be used alone or combined with one or more modules of the same or another program. Although various steps and modules are described, it is not required to include all steps or all modules in software 20. It is within the scope of this disclosure to carry out the steps and/ore modules in different order(s) than presented here. For example, in the modules described below, main module 94 is described after menu module 78 so that it can be better understood how main module 94 can—optionally and selectively—be programmed in certain circumstances to start menu module 78.

As shown in FIG. 4A, optional menu module 78 can be implemented during a call to notify a caller of the availability of enhanced services and to explain how to access these services. Menu module 78 is provided as shown in FIG. 4A and includes initial call routing determination step 80 that detects or determines whether the call should be routed directly to an operator station or should instead be routed to a call tour. If the call is to be directly routed, then the step 82 of routing the call to the operator station is performed. If the call is not to be directly routed, then the step 84 of playing a call tour is performed. In the example of FIG. 4A, one or more services are offered in a services offering step 86, and the caller is prompted to make a choice or confirm the selection of the one or more services in step 88. Upon entry of a number by the caller and resulting generation of a DTMF tone, the step 90 of detecting and receiving the DTMF tone is performed. The DTMF tone generated by the caller is at step 92 compared to the corresponding services, and if the tone generated matches a service, the step 82 of routing the call to the proper operator station is performed. If the DTMF tone generated does not correspond to a service, steps 84 and following may be repeated, or the call can be routed elsewhere. As known to one of ordinary skill in the art, other methods of selection can be utilized such as detecting a spoken number or other verbal utterance.

As shown in FIG. 4B, main module 94 can be implemented to determine what services to offer during a call. Main module 94 is illustratively implemented when a call is received at routing system 15. Main module 94 includes providing an initial call reception step 96 in which a call is received at routing system 16, at which point it is tested to determine what to do with the call. After call reception step 96, routing system 16 performs initial routing step 98, in which routing system 16 determines whether the call includes entry of an access number (again, which access number may take many forms) to one or more of the enhanced services.

As such, initial routing step 98 is performed in which main module 94 detects based on entry of an access number whether call routing can be determined from the access number. If routing can be determined, call-routing-known step 110 is performed which routes the call to one of several possible destinations. The destination can be based on the access number and can be, for example, operator equipment 14 for direct live access to an operator. Optionally, call-routing-known step 110 may, based on the access number, access menu module 78 which is then implemented as described above. If call routing cannot be determined, then call-routing-unknown step 112 is performed. In this case, again optionally, the call can be routed to operator equipment 14 (such as to permit a live operator to determine the service and/or payment method), menu module 78 can be implemented, or the call can be connected to a variety of other call tours, and the like.

As shown in FIG. 4C, line condition module 114 can be implemented during a call. Line condition module 114, tests for the condition of the line and presents a caller with one or more options for enhanced services given certain line conditions. For example, menu module 78 may be played upon detection of a ring-no-answer line condition, offering e-mail services. Additional line conditions may be used to trigger playing a call tour, connecting to the operator equipment, or the like. By way of example and not limitation, the line conditions monitored may include a busy signal, a connection, a non-connection (such as when the one party has hung up), an automatically played message (such as when line trouble is detected), connection with a voicemail system, connection with an answering machine, detection of entry of a DTMF tone or signal, speaking of a particular word or phrase, and other detectable line conditions.

Line condition module 114 includes line observing step 116 and testing sequence 118, in which the line condition is tested for a series of conditions. Testing sequence 118 may include one or more of the following steps, depending on which type of line condition is to trigger an offering of enhanced service(s). Testing sequence may include the step 120 of detecting a busy signal, the step 122 of detecting a DTMF tone, and/or the step 124 of detecting a connection. Steps 120 through 124 are provided for illustration, and it is within the scope of this disclosure to include other detectable line conditions, such as those listed above, in place of or in addition to one, more, or all of the steps 120, 122, 124. Although referred to as a “sequence,” testing sequence 118 may only test for a single condition.

As illustratively depicted in FIG. 4C, testing sequence 118 tests the line for a busy signal, a DTMF tone or signal, and counts the number of times that testing sequence 118 is performed using a counting step 128. At concluding step 129 a ring no answer (RNA) is determined to be present. A timing step 126 may be used in place of a counting step 128, so that after completing a certain number of passes through testing sequence 118 or after a given time has elapsed, line condition module 114 can be programmed to play a call tour to offer enhanced services.

As shown by way of example in FIG. 4C, if the line condition test is positive in response to step 120 detecting a busy signal, the step 130 of playing a first call tour is performed. If the line condition test is positive in response to step 122 detecting a DTMF, the step 132 of playing a second call tour is performed. If the line condition test is positive in response to step 124 detecting a connection, then a circuit can be left open to continue to monitor the line, for example to offer services after the called party hangs up or to offer services if a DTMF tone is detected. Alternatively, upon such a connection if no services are to be offered, the line condition module 114 can be ended with no further monitoring of the line.

Each line condition, as with each access number and manner of access to routing system 16, may have a unique call tour, or a plurality of line conditions may have the same call tour. An illustrative call tour includes a pre-recorded message which is played to the caller, the message relating to the specific call tour. In another configuration, the call is not connected to a menu module or call tour, and is connected directly to operator equipment. For example, the caller first hears a human operator offering enhanced services instead of a call tour with a message played offering such service.

In the configuration where a call tour such as menu module 78 is played to notify the caller of available services, a pre-recorded message 152 is played to the caller. E-mail service 148 may be offered in message 152 when line condition 154 meets one or more conditions. For example, if line condition 154 is a ring-no-answer condition 156, then message 152 is played which notifies the caller that s/he can initiate e-mail service 148 by performing a selecting step 158, such as depressing a character, remaining on the line, or performing some other activity. If the caller does not wish to initiate e-mail service 148, s/he simply does not perform the selecting step 158, and the call is either terminated or another menu or feature may be offered to the caller.

If the caller performs selecting step 158, the caller is connected to operator equipment 14 and is now on the line with a human operator having access to an information device 26, an e-mail terminal or device 32, or workstation 44. The operator may instruct the caller about use of e-mail service 148, provide billing information and rates, and other relevant information. The operator requests information such as e-mail address of recipient(s), e-mail body text, subject line text, any return e-mail address, and the like. To perform the e-mail service 148, the operator then enters using e-mail device 32 as shown in FIG. 3, or workstation 44 as shown in FIG. 5, information such as recipient e-mail address, any return e-mail address, subject line text, e-mail body text, and the like, and sends the e-mail on behalf of the caller. As shown in FIGS. 3 and 5 respectively, an information device, such as e-mail device 32 or work station 44, is coupled to a network of computers or other e-mail receiving devices, such as the Internet. Any suitable software to facilitate generation and sending such messages may be used.

If the caller is connected to a live operator instead of a call tour, the caller performs selection step 158 by simply notifying the operator which service s/he wishes to use, or whether or not s/he wishes to use a service. The routing system 16 may have already made the determination which service is to be provided and connected the call to the proper operator. As illustratively shown in FIG. 5, if the operator has the skill set, and operator equipment 14 is suitable to perform the service, ACD switch 48 is configured to cooperate with routing system 16 to queue or connect the call based on information detectable about the call or routing information gleaned as provided above. It is within the scope of this disclosure for the operator to activate the modules of FIGS. 4B-E, or otherwise access portions of enhanced services platform 10 as necessary to connect the caller to a suitable operator or to complete the desired service.

As shown in FIG. 4D, software 20 may include a payment module 160 relating to payment information. Payment module 160 performs step 162 to detect whether the number being dialed is an access number from a pre-paid calling card. Illustratively, computer 50 performs the step 164 of querying memory 52, such as database 56, for whether the dialed number is such a pre-paid access number. If it is, then the caller is prompted at step 166 to enter a personal identification number or other number (collectively PIN) established for that pre-paid calling card.

A separate link, illustratively a “HIL tracking link,” is established at step 168 to monitor how much of pre-paid time has been used. As the account is monitored at step 170, when the pre-paid account is empty, the call is terminated. In the illustrative context of a prepaid card shown in FIG. 4D, this is accomplished through the step 168 of creating a connection with a database, such as Oracle database server 75. It is within the scope of this disclosure to continue to monitor the account or to determine once the available amount on the card (and terminate the link after this determination). The service is terminated upon depletion of the account or the available amount.

As shown in FIG. 4D, an optional payment sub-module 270 may be included which serves to query other databases to determine of a payment method is valid. At step 272 validation engine 62 is queried for whether validating information is known locally. Validation engine 62 at step 274 queries memory 52 (illustratively Oracle database application server 74) for whether validating information is known or stored locally, for example in databases 54 or 56. A determination is made at step 276 whether the information is so known, and if it is, at step 278 a live operator may be connected, a particular call tour played, or other options. If step 276 returns a negative answer indicating that the information contained locally does not validate a payment method, at step 280 a link may be established with an outside database such as database 58. At step 282, database 58 is queried for whether validating information is known about the call. If validating information cannot be determined, the call may be terminated or another call tour or a live operator may be presented. If the validating information is obtained, the step 284 of monitoring the credit remaining in an account. Monitoring, as stated above, may be a one-time gathering of the available credit up to and including real-time monitoring of an account's available credit. Once the credit is depleted, the call may be terminated. Again, it is within the scope of this disclosure to offer the caller other call or payment alternatives instead of terminating the call upon depletion of credit in the account. For example, the caller could be prompted to insert coins at a pay phone, enter a calling card number or another prepaid number, or other suitable payment alternatives, some of which are discussed herein.

Once the caller enters an acceptable PIN, the caller is connected at step 172 to an operator or a menu module offering enhanced service(s). If the PIN is not accepted, or if the number being called is not a pre-paid number, then another method of payment is requested at step 174 by a live operator or by another call tour. The caller then enters or provides alternative payment information, for example calling or credit card numbers, third party billing numbers, and the like. If this information, when analyzed, is acceptable, then the caller is connected with an operator who is capable of providing the desired service(s). If this information is not acceptable, the call can either be terminated or the caller can be connected to a general purpose operator, or offered other services or options as appropriate.

Because, in this embodiment, another module detects whether the originating number supports the desired enhanced service(s), the payment module 160 does not include instructions to connect the caller to the operator if the originating number itself supports the enhanced service requested (such as when a call is placed from a home telephone, a cellular phone, or a business phone). However, in an alternative embodiment, this step or function of determining whether a caller is calling from a number that can be billed for the services could be performed in payment module 160. It is within the scope of this disclosure for payment module 160 to be performed, if at all, prior to a call being routed through switch 22 to operator services architecture. In other words, whether or not the payment method attempted is valid can be determined prior to or alternatively after initially accessing part of enhanced services platform 10.

Enhanced services platform 10 is a flexible system that can be configured to permit access to the enhanced services in a variety of ways, and can be configured to accept a variety of forms of payment. For example, a caller calling from home or work may simply charge the service by dialing 1 (one)+an access number for the service; this type of call is sometimes referred to as a “1+call.” Payment may be rendered in other ways, for example by using a prepaid phone card, credit card, a calling card, billing the service(s) to a third party number, coin payment in a pay phone, or other suitable billing methods.

As shown in FIG. 4E, operator system (OS) module 176 is illustrated. Optionally, OS module 176 is accessed after the payment method for a requested service is approved, as previously described. It is within the scope of this disclosure to provide access to OS module 176, and determine and approve payment method after such access. When OS module 176 is accessed, step 178 of determining how such access was made may performed. It is within the scope of this disclosure that OS module 176 does not include step 178 of determining access method; for example, this determination may have already been made in another module or elsewhere.

Referring again to FIG. 4E, if the number dialed was specifically to an e-mail service 148 access number, then the call is connected at step 180 with operator equipment 14 accessible by an e-mail operator. The number dialed may have been a toll free number, a local number, or any other sequence of digits that selects the e-mail service, such as within a call an selecting an option from a menu such as menu module 78. Alternatively, the number may be that for translation services, in which case the call is routed at step 182 to a bilingual operator capable of performing the translation service. It is within the scope of this disclosure to play a call tour or to provide a specific access number which identifies the call as one which needs translation for a particular language or dialect. For example, a given access number may be the access number which routes the call directly to a Spanish and English-speaking operator, or to a Japanese and English-speaking operator.

Illustratively, if the number dialed is not an access number specifically for e-mail, or designated in a database as a number to be connected with e-mail service 148, then a more general call tour, menu of offerings, or an operator, can be presented at step 185 to the caller.

As shown in FIG. 4E, once the e-mail operator is connected, the e-mail operator can provide instructions on how the e-mail service works, how much the service costs, and the like. The operator requests required information, and the caller provides the information. Optional information can also be provided, for example a subject line, a salutation, a callback number, and the like. Regardless of whether prompted by the operator or provided by the user without prompting, the step 184 of entering information provided by the caller is performed by the operator using operator equipment 14. E-mail terminal 32 is used to enter the required e-mail fields and other desired fields, and may contain any software capable of creating and sending an e-mail, such as Microsoft Outlook®, GroupWise®, and the like. The e-mail operator may confirm the contents of the e-mail with the caller at step 186 to confirm accuracy. The e-mail operator then performs step 188 sending the e-mail over the network, such as the Internet.

The amount owed for e-mail service 148 can be calculated in any number of ways, including a flat fee per e-mail, a fee for each addressee, a charge for the time it takes to create the e-mail, a charge by number of words, etc. Also, a caller may be presented with a choice of how he wants to pay.

As illustrated in the portion of FIG. 4E showing the translation services, the bilingual operator can be first accessed before a third (or other) party is connected to the caller. The third party can be connected at step 190 either by the operator or by the caller. Otherwise, in one particular configuration, the caller can access the bilingual operator during the course of a call at step 192. As described above illustratively, the line condition module 114 may be running, which determines that a caller who is in a call has depressed, for example, a number which indicates that the call is to be connected to a bilingual operator.

After the caller is connected with an operator capable or equipped to provide translation service to the caller, and the caller is also connected to the desired third (or other) party, the bilingual operator performs the step 194 of translating the conversation as needed. It is within the scope of this disclosure for the connections to be established and controllable to refine the process of translation. It is within the scope of this disclosure to adjust the volume to one party or the other so that while the one party is speaking, the other party does not hear the one party at full volume (or at all), and while the operator is speaking to the other the other hears the operator at full volume, and vice versa.

After the service is rendered, the billing amount is calculated and charged at step 196 against or to the proper account. Again, various billing methods may be used to pay for the enhanced service, including but not limited to a flat fee for a local translation, a charge per unit time, a charge per unit of time that varies based on a number of factors such as time of day, number called, originating ANI, and the like.

As shown in FIGS. 1-3, operator equipment 14 is provided, enabling an enhanced services operator to communicate with the caller and perform enhanced services such as e-mail service 148 and translation service 150. FIG. 2 shows an illustrative system including operator equipment 14 to enable the enhanced services operator to provide translation services. Operator equipment 14 is operatively coupled to computer 50 and/or memory 52 and/or switch 22, providing the operator with the ability to access various databases as needed, to access other networks as needed, and to connect calls requested by the caller. Operator equipment 14 is illustrated as including operator communications device 26, which illustratively includes a listening device 28, a speaking device 30, and an information device such as work station 44 or e-mail terminal 32. These devices can be separate devices (for example a separate headset, separate microphone, and separate computer) or one or more of the devices can be part of a unitary apparatus. For example, such an apparatus could be a computer having speakers and a built-in microphone, permitting the operator to engage in 2-way communication with the caller and access databases using the computer. The connection with such databases could be through a separate link or through link 17 described above.

FIG. 3 shows an illustrative system including operator equipment 14 to enable the enhanced services operator to provide e-mail services. E-mail operator equipment 14 in this example is similar to that described with reference to FIG. 2. Operator equipment 14 of FIG. 3 is operatively coupled to computer 50 and/or memory 52 and/or switch 22, providing the operator with the ability to access various databases as needed, to access other networks as needed, and to connect calls requested by the caller. E-mail operator equipment 14 is illustrated as including operator communications device 26, which illustratively includes a listening device 28, a speaking device 30, and an information device. In the case of the e-mail operator equipment 14, information device is an e-mail terminal 32 operatively coupled to a network of communication devices capable of receiving electronic messages (e-mail), such as the Internet. The connection with this network can be through a separate link or can be through link 17 described above.

In one exemplary embodiment, shown in FIG. 5, ACD switch 48 is operably coupled by HIL release link trunks 67 to local switch 68, illustratively a second Harris 20/20 switch similar to ACD switch 48. Illustratively, local switch 68 includes two links 69, 70 to auto op computer 60. One is a T1 link 69. In this example, link 69 includes twenty-four (24) voice channels coupled to the communications card. The second link is the Host Interface link (HIL) 70 which is coupled to a RS232 serial communications port (not shown). In this example link 70 carries out-of-band signaling used to control the 24 voice channels. The HIL protocol is described in detail in VoiceFrame Programming—Reference Manual, Manual 958935-01, Harris Corporation, Digital Telephone Systems Division 1991, which is expressly incorporated herein by reference. Although specific links, ports, and communications protocols are disclosed, it will be recognized by those of ordinary skill in the art that other types of links, ports, and protocols are within the scope of this disclosure.

Based on call information and the routing determined therefrom, routing system 16 may determine that the call should be routed to operator equipment 14. Thus, local switch 68 completes a circuit between caller equipment 18 and operator equipment 14, along link 67 such as the illustrative RLT T1 link of FIG. 5. The call and information is sent from local switch 68 to ACD switch 48 (illustratively by out of band signaling) along link 67. Information passed illustratively includes originating number and/or ANI, access number, an ACD pattern number used to determine which operator equipment 14 to connect the call to, and the like. ACD switch 48 connects the call to a suitable operator teleset 42 based on which such operator teleset 42 corresponds with an operator having the skill set to provide the required service. The proper operator teleset 42 is illustratively selected by looking at the ACD pattern number stored in memory 52. The call is routed to available operator equipment 14 that is logged into the desired pattern as defined by ACD switch 48 cooperating with memory 52.

In one example, once a call is presented to a particular operator, that operator is provided certain information regarding the call based on a call tour, similar to the above description relating to call tour selection. The call information in this example is presented on the operator information device, such as operator work station 44. The call information and voice signals are carried to operator equipment 14 on link 17, illustratively a WIL Release Line Trunk (RLT) link, as shown in FIG. 5. Operator equipment 14 includes an operator teleset 42 coupled to, for example, an operator headset (or listening device 28 and speaking device 30) and operator workstation 44. Operator teleset 42 is operatively coupled to ACD switch 48 with a link 17 such as illustrative 1 B+D digital link. The data and voice signals are decoded from a single digital signal at operator teleset 42 into separate voice channel and a data channel. The voice channel is connected by a link to, for example, an operator headset. The data is sent from teleset 42 to operator workstation 44 through a link 71, illustratively an RS232 link as shown in FIG. 5. This process is reversed when sending information from the workstation and headset to the teleset.

As suggested by FIG. 5, ACD switch 48 and teleset 42 cooperate to connect the call to operator equipment 14. Data about the call (for example the originating number and the access number) is sent to the operator equipment 14, illustratively from teleset 42 to workstation 44 through link 71. The information is examined and processed similar to processing described above relating to auto op computer 60. The WIL protocol is described in the VoiceFrame Programming Reference Manual available from Harris Digital Telephone Systems Division, 1991. The access number and originating number are passed to the oracle database services through a link, illustratively a TCP/IP connection, on LAN 72. The database services cooperate with a live operator program running on the operator work station, to determine what information to present to the operator.

The live op program is illustratively resident on the operator workstation 44 and prompts the operator with a call tour having a script the operator speaks to the caller. In an illustrative e-mail call tour, the operator is prompted to ask the caller for the destination e-mail address, caller's e-mail address, caller's name, message, and the like. After the operator enters all information into workstation 44, the operator executes a command to send the e-mail. The e-mail message is illustratively sent through the Ethernet LAN connection to an e-mail server where the message is formatted and sent to the recipient over the Internet.

With reference to FIG. 3, again, devices 28, 30, and 32 can be separate devices (for example a separate headset, separate microphone, and separate computer) or one or more of the devices can be part of a unitary apparatus. For example, such an apparatus could be a computer having speakers or headphones and a built-in microphone, permitting the operator to engage in 2-way communication with the caller and access databases and/or the network or Internet, as mentioned in the previous paragraph, using the computer.

Link 17 which links operator equipment 14 to other parts of the system may be, in practice, a plurality of links. For example, as shown in FIG. 5, three separate links operatively connect a given operator to various parts of the system. The operator has access through Ethernet 220 to computer 52, has a direct connection to validation engine 62, and another connection into switch 22, specifically to ACD switch 48. In this way, the connection between operator and caller can be maintained, but when it is no longer necessary to have the connection routed through computer 50 (because, illustratively, no information or processing by computer 50 is then required), the connection can be maintained directly between the operator, through switch 22, and to caller equipment 14, freeing computer 50. One of ordinary skill in the art will recognize that various connection types and paths are within the scope of this disclosure.

The operator may have additional information available through other memory or databases 58, or by way of, for example, a connection to the Internet or another network of communications devices. Such access to the computer, memory, databases, or other sources of information may assist the operator in performing enhanced services such as e-mail and translation. For example, the operator may have access to a translation dictionary to permit the operator to look up words the operator is having difficulty translating from memory. Also for example, the operator may have access to a database of e-mail addresses. Such a database may be pre-established by the caller and only accessible by the caller or may be more commonly available.

FIG. 9 is a system level block schematic diagram of an embodiment of the enhanced services platform 10. The configuration of the enhanced services platform 10 shown in FIG. 9 is merely illustrative. Enhanced services platform 10 includes a routing system 900. The routing system 900 comprises a routing system 16, as routing system 16 is described above. The routing system 900 may be communicably coupled to a calling station 910 via link 912 and to a called station 920 via a link 922. The calling station 910 and the called station 920 may each comprise similar components as caller equipment 18, which is described above. The calling station 910 and the called station 920 may also each comprise a wireless terminal, a desktop computer, a server, a laptop computer, a personal digital assistant (PDA), a pocket PC, a wireless telephone, a corded telephone set, a cordless telephone set, a cellular telephone, a satellite telephone, a PCS telephone or device, an intercom, or any other audio and/or video communication device.

The routing system 900 may also be communicably coupled to an operator station 930 via a link 932. The operator station 930 may comprise similar components as operator equipment 14, which is described above. The operator station 930 may also comprise the automated operator computer 60, which is described above. Additionally, the operator station 930 may comprise a wireless terminal, a desktop computer, a server, a laptop computer, a personal digital assistant (PDA), a pocket PC, a wireless telephone, a corded telephone set, a cordless telephone set, an intercom, or any other audio and/or video communication device.

The links 912, 922, and 932 may each include, for example, a global network, such as the Internet, a wide area network (WAN), a local area network (LAN), wireless communication networks, a wireless local area network (WLAN), satellite networks, Bluetooth networks, a synchronous optical network (SONET), plain old telephone service (POTS) network, voice-over-IP (VoIP) networks, asynchronous transfer method (ATM) networks, integrated digital subscriber network (ISDN), frame relay networks, or other types of communications networks capable of carrying audio communication.

In operation, the routing system 900 receives a call from the calling station 910 via link 912. This call includes information that allows the routing system 900 to route the call to the called station 920 via link 922. The call may also include information indicating that the routing system 900 should monitor the communication portion of the call for a trigger signal while the calling station 910 and the called station 920 are engaged in communication. When the routing system 900 detects the trigger signal, the call is further routed to the operator station 930 via a link 932.

The call may be routed immediately to the operator station 930, so that the calling station 910, the called station 920, and the operator station 930 are all communicably coupled without significant delay. Alternatively, either the calling station 910 or the called station 920 may be put on hold while the other station 910 or 920 is bridged to the operator station 930, and then after some delay the station 910 or 920 on hold may be bridged back into the call. For example, when the trigger signal is initiated by the calling station 910, the called station 920 may be put on hold while a brief communication occurs between the calling station 910 and the operation station 930. For further example, when the trigger signal is initiated by the called station 920, the calling station 910 may be put on hold while a brief communication occurs between the called station 920 and the operator station 930. As indicated above, the trigger signal may be any line condition, such as a DTMF tone, a particular spoken word of phrase, an independently generated signal, or a signal generated by a custom developed calling station 910 and/or called station 920.

FIG. 10 is a more detailed system level block schematic diagram of an embodiment of enhanced services platform 10. The configuration of the enhanced services platform 10 shown in FIG. 10 is merely illustrative. As shown in FIG. 10, the routing system 900 comprises a first interface 1002, a second interface 1004, a third interface 1006, a processor 1008, and a switch 1010. The switch 1010 may include similar equipment to the switch 22, as described above. The switch 1010 may also include switch relays 1012 and 1014, which are shown greatly simplified for illustration purposes. The processor 1008 may include a signal processor 1030, which is shown illustratively as a digital signal processor (DSP), but could be any type of signal processor, such as, for example, an analog signal processor, a speech recognition unit, a voice response unit, a DTMF decoder, or the like. Alternatively, the signal processor 1030 may be separate from yet communicably coupled to processor 1008, for example as a peripheral device.

The first interface 1002 may be communicably coupled to a network 1052 via link 912. The second interface 1004 may be communicably coupled to a network 1156 via link 922. The third interface 1006 may be communicably coupled to a network 1054 via link 932. The networks 1052, 1054, and 1156 may each include, for example, other switches 34 and other links 36, such as are found in the public telephone network. The networks 1052, 1054, and 1156 may each be a sub-network of a larger network, or may all be the same network, such as network 40 shown in FIG. 5.

The first interface 1002 may also be communicably coupled via link 1022 to the switch 1014 and to the switch relay 1012, and via link 1034 to the signal processor 1030. The second interface 1004 may be additionally communicably coupled via link 1022 to the switch relay 1012. The third interface 1006 may be communicably coupled via link 1026 to the switch relay 1014. The processor 1008 may be communicably coupled, via links 1036 and 1032, respectively, to the switch relay 1012 and the switch relay 1014.

FIG. 11A is a flow diagram describing an illustrative method of operation for the routing system 900. At 1102, the calling station 910 initiates a call. For example, where the calling station 910 is a telephone, a number is dialed at the calling station 910. The routing system 900 receives the call at 1104. For example, the routing system 900 may receive the call via the network 1052, or directly from the calling station 900 via the link 912. The routing system 900 may receive information about the call, including a called number associated with the called station 920, and a calling number associated with calling station 910, and the routing system may access a database 1106 to retrieve information about the calling station 910. For example, the first database 54 contained in the memory 52 (as shown illustratively in FIG. 5) may include originating number data to determine whether specific services are supported for the calling station 910.

At 1108, the routing system 900 determines whether a particular service is supported for the calling station 910, and if not then the call may be connected to the called station 920 in the usual manner, without enhanced services, as shown at 1110. If, on the other hand, the routing system 900 determines at 1108 that a particular service is supported for the calling station 910, then at 1112 the routing system 900 allocates the signal processor 1030 to monitor the call communication path.

Continuing on to FIG. 11B, at 1114 the routing system 900 connects the call to the called station 920. For example, the processor 1008 may signal switch relay 1012 to close, thereby communicably coupling the calling station 910 to the called station 920. At 1116, after the calling station 910 and the called station 920 are communicably coupled, the signal processor 1030 monitors the call for a trigger signal. If the trigger signal is not detected, then at 1118 the signal processor 1030 continues to monitor for the trigger signal. If the trigger signal is detected by the signal processor 1030 at either 1116 or 1120, then at 1122 the routing system may look up preferences associated with the calling station 910. At 1124 the routing system 900 may determine whether there are valid preferences stored in a database for the calling station 910. If no preferences are found, then at 1126 the automated operator computer 60 may prompt for the selection of preferences from the calling station 910. At 1128, these preferences may be stored in a database for future use.

If the routing system determined at 1124 that preferences were on file, or after preferences have been stored at 1128, at 1130 the routing system 900 may bridge the operator station 930 into the call. For example, the signal processor 1030 may signal the processor 1008 that the trigger signal was detected, and the processor 1008 may signal the switch relay 1014 to close, thereby communicably coupling the calling station 910 to the operator station 930. Alternatively, the processor 1008 may also signal the switch relay 1012 to open, thereby placing the called station 920 on hold. In this manner, the calling station 910 and the operator station 930 may communicate privately for a period of time. After this period of time, the processor 1008 may signal the switch relay 1012 to close again, thereby bridging the called station 920 back into the call with the calling station 910 and the operator station 930.

Links, as used herein, may take many forms. It is within the scope of this disclosure for links to include wires, cables, wireless connections (such as those using transmitters and receivers), switched networks, packet networks, Ethernet networks, global networks such as the Internet, frame relay networks, public switched telephone networks such as network 40, ATM networks, fiber optic networks, and similar technologies. As used herein, the terms line, connection, and call are intended to cover any type of connection through any medium capable of transmitting or conducting information in any form. The terms line, call, and connection are not intended to be limited to a physical connection or coupling, but may include indirect connections or couplings.

Although the invention has been described in detail with reference to certain preferred or illustrative embodiments, variations and modifications exist within the scope and spirit of the invention as described and as defined in the claims. 

1. A routing system for providing a communications service via a telecommunications network comprising: a switch; a first interface communicatively coupled to the switch and operable to relay an audio signal between a calling station and the switch; a second interface communicatively coupled to the switch and operable to relay the audio signal between a called station and the switch; a third interface communicatively coupled to the switch and operable to relay the audio signal between an operator station and the switch; and a signal processor communicatively coupled to the switch and operable to monitor the audio signal for a trigger signal as the audio signal is relayed between the first interface and the second interface; wherein the signal processor is further operable to selectively activate the switch upon detection of the trigger signal to communicably couple the first interface to the third interface.
 2. The routing system of claim 1, wherein the signal processor comprises a digital signal processor.
 3. The routing system of claim 1, wherein the signal processor comprises a DTMF decoder.
 4. The routing system of claim 1, wherein the trigger signal is a DTMF tone.
 5. The routing system of claim 1, wherein the signal processor comprises a speech recognition unit.
 6. The routing system of claim 1, wherein the trigger signal is a spoken word.
 7. The routing system of claim 1, wherein the trigger signal is transmitted by the calling station.
 8. The routing system of claim 1, wherein the trigger signal is transmitted by the called station.
 9. The routing system of claim 1, wherein the calling station is associated with a calling telephone number and the switch is further operable to route the call to the third interface as a function of the calling telephone number.
 10. The routing system of claim 1, wherein the calling station comprises a telephone selected from the group consisting of a corded telephone, a cordless telephone, a cellular telephone, a PCS telephone, and a satellite telephone.
 11. A routing system for providing a communications service via a telecommunications network comprising: a switch; a first interface communicatively coupled to the switch and operable to relay an audio signal between a calling station and the switch; a second interface communicatively coupled to the switch and operable to relay the audio signal between a called station and the switch; a third interface communicatively coupled to the switch and operable to relay the audio signal between an operator station and the switch; a processor communicatively coupled to the switch operable to receive a switching signal from the telecommunications network and selectively activate the switch as a function of the switching signal to communicably couple the first interface to the second interface; and a signal processor communicably coupled to the switch; wherein signal processor is operable to monitor the audio signal as the audio signal is relayed between the first interface and the second interface, and to selectively activate the switch as a function of the audio signal to communicably couple the first interface to the third interface.
 12. The routing system of claim 11, wherein the signal processor comprises a digital signal processor.
 11. The routing system of claim 11, wherein the processor comprises the signal processor.
 14. The routing system of claim 11, wherein the processor is a service switching point.
 15. The routing system of claim 11, wherein the signal processor comprises a DTMF demodulator.
 16. The routing system of claim 1, wherein the signal processor comprises a speech recognition unit.
 17. A method for providing a translation service via a network comprising: receiving a call at a local exchange from a calling communication device associated with a first number; indexing the first number into a database and selectively routing the call to a switch as a function of the first number; receiving the call at the switch; receiving a second number associated with a called communication device from the calling communication device; routing the call through the switch to a called communication device as a function of the second number; monitoring the call between the calling communication device and the called communication device for an audio signal with a processor; and routing, upon detection of the audio signal, the call through the switch to an operator communication device.
 18. The method of claim 17, wherein monitoring the call between the calling communication device and the called communication device for an audio signal with a processor comprises detecting a tone.
 19. The method of claim 18, wherein detecting a tone comprises detecting a DTMF tone.
 20. The method of claim 17, wherein monitoring the call between the calling communication device and the called communication device for an audio signal with a processor comprises detecting a spoken word.
 21. A routing system for providing a communications service via a telecommunications network comprising: a switch; a first interface communicatively coupled to the switch and operable to relay an audio signal between a calling station and the switch; a second interface communicatively coupled to the switch and operable to relay the audio signal between a called station and the switch; a third interface communicatively coupled to the switch and operable to relay the audio signal between an operator station and the switch; a processor communicatively coupled to the switch operable to receive a switching signal from the telecommunications network and selectively activate the switch as a function of the switching signal to communicably couple the first interface to the second interface; and a signal processor communicably coupled to the switch; wherein signal processor is operable to monitor the audio signal as the audio signal is relayed between the first interface and the second interface, and to selectively activate the switch as a function of the audio signal to communicably couple the second interface to the third interface.
 22. The routing system of claim 21, wherein the signal processor comprises a digital signal processor.
 23. The routing system of claim 21, wherein the signal processor comprises a DTMF decoder.
 24. The routing system of claim 21, wherein the trigger signal is a DTMF tone.
 25. The routing system of claim 21, wherein the signal processor comprises a speech recognition unit.
 26. A method for providing a translation service via a network comprising: receiving a call at a routing system from a calling communication device associated with a first number; indexing the first number into a database and selectively routing the call to a switch as a function of the first number; receiving the call at the switch; receiving a second number associated with a called communication device from the calling communication device; routing the call through the switch to a called communication device as a function of the second number; monitoring the call between the calling communication device and the called communication device for an audio signal with a processor; and routing, upon detection of the audio signal, the call through the switch to an operator communication device.
 27. The method of claim 26, wherein monitoring the call between the calling communication device and the called communication device for an audio signal with a processor comprises monitoring the call between the calling communication device and the called communication device with a digital signal processor.
 28. The method of claim 26, wherein monitoring the call between the calling communication device and the called communication device for an audio signal with a processor comprises monitoring the call between the calling communication device and the called communication device with a DTMF decoder.
 29. The method of claim 26, wherein monitoring the call between the calling communication device and the called communication device for an audio signal with a processor comprises monitoring the call between the calling communication device and the called communication device with a speech recognition unit.
 30. The method of claim 26, wherein routing, upon detection of the audio signal, the call through the switch to an operator communication device, comprises routing, upon detection of a DTMF tone, the call through the switch to an operator communication device 